Dynamic data set modification and mapping

ABSTRACT

Systems and methods for generating a data map based on a dynamically updated data set. The system includes a client-side device. The client-side device includes a controller and is operably connected to a communication network. The controller includes a processor and a non-transitory computer readable data storage medium, the processor is configured to retrieve from the medium and execute computer readable instructions to receive a data set including one or more data assets and generate the data map based on the received data set. Each data asset includes four or more attributes. The data map includes one or more segments, and the one or more segments illustrate each of the four or more attributes of the one or more data assets.

RELATED APPLICATIONS

This application is a U.S. continuation application of and claims thebenefit of PCT Patent Application No. PCT/US17/40694, filed on Jul. 5,2017, and also claims the benefit of U.S. Provisional Patent ApplicationNo. 62/358,419, filed Jul. 5, 2016, and U.S. Provisional PatentApplication No. 62/514,084, filed Jun. 2, 2017, the entire contents ofeach of which are hereby incorporated by reference.

FIELD OF INVENTION

This invention relates to the dynamic modification of data sets on boththe client side and server side of a data modification and mappingsystem.

SUMMARY

Information is critical to knowledge, understanding, and decisionmaking. However, when making decisions, decision makers are oftenpresented with too little information, such that a decision is beingmade based on an incomplete view of an issue, or with too muchinformation, such that the amount of information overwhelms the issueand prevents evaluation of the issue in a meaningful way. In the modernday, the obstacle inhibiting good decision making is often the presenceof too much information, not too little. The management and organizationof data or information, and being able to effectively convey or presentthat data or information to an individual is important to evaluating andunderstanding an issue.

Data or information is rarely entirely unstructured. In fact,information and data can often be broken down into a hierarchicalstructure based on attributes or parameters. This structured orsemi-structured data can be compiled into data sets and, based on thestructure of the data, represented meaningfully as a map (e.g., a radialmap) of the data. A master or parent data set containing all of the datafor a given map can be dynamically modified based on, for example, usermodifications to the map, data added to the map, multi-map data setcompilation, etc. By dynamically modifying data sets and allocating dataprocessing of certain tasks to either the client-side or the server-sideof a data manipulation and mapping system, the operation of both theserver-side and the client-side can be improved, as well as theeffectiveness of the mapped data sets. For example, by pushing some dataprocessing from the server-side to the client-side, the server iscapable of handling additional traffic or running more computationallyexpensive programs based on data received back from the client-side.Additionally, by dynamically modifying data sets on the client-side, theclient device limits the amount of data (e.g., as a subset of the masterdata set) that the client device needs to process to generate a mapbased on the data set. As a result, a robust dynamic mapping of datasets is achieved from a client-side device with relatively limitedprocessing capability (e.g., a smartphone, a tablet, etc.).

After a data set has been generated or selected, the structured datawithin the data set is used to generate a hierarchical map thatrepresents the data using, for example, four or more dimensions ofinformation. Each dimension provides meaningful information to a user toassist the user in understanding the data set and the data containedwithin the data set. For example, a radial data map can be used tomeaningfully represent data assets based on relative positions of thedata assets within a given radial segment of the map. The segment of themap itself represents a first dimension of the map and illustrates thesegment's place in a given hierarchical structure, as well as the numberof additional segments at the same layer of the hierarchical structure.The shape (e.g., as a square, a circle, a triangle, etc.) and color(e.g., red, green, blue, etc.) of an asset as represented in the segmentrepresent second and third dimensions of the map and illustrates thetype and/or a property of data asset that is present in the segment. Theradial positioning of the data asset within a given segment represents afourth dimension of the map. In some embodiments, the radial positioningof the data asset represents a relative age of the data asset, arelative importance of the asset, etc. The positioning of the data assetcircumferentially along the segment arc represents a fifth dimension ofthe map. In some embodiments, the positioning of the data asset alongthe segment arc represents a relative age of the data asset, a relativeimportance of the asset, etc.

In one embodiment, the invention provides a system for generating a datamap based on a dynamically updated data set. The system includes adatabase and a server. The server includes a controller and is operablyconnected to a communication network. The controller includes aprocessor and a non-transitory computer readable data storage medium.The processor is configured to retrieve from the medium and executecomputer readable instructions to retrieve a data set from the database,transmit the data set to a client-side device over the communicationnetwork, receive a modified data set from the client-side device overthe communication network, and store the modified data set from theclient-side device in the database. The data set includes one or moredata assets and each data asset includes four or more attributes. Thedata map is generated based on the retrieved data set.

In another embodiment, the invention provides a system for generating adata map based on a dynamically updated data set. The system includes aclient-side device. The client-side device includes a controller and isoperably connected to a communication network. The controller includes aprocessor and a non-transitory computer readable data storage medium.The processor is configured to retrieve from the medium and executecomputer readable instructions to receive a data set including one ormore data assets and generate a dynamic data map based on the receiveddata set. Each data asset includes four or more attributes. The dynamicdata map includes one or more segments, and the one or more segmentsillustrate each of the four or more attributes of the one or more dataassets. The processor is also configured to retrieve from the medium andexecute computer readable instructions to select one or more of the oneor more segments of the dynamic data map and limit a set of data assetsloaded into an active memory of the controller to the data assetsassociated with the selected one or more of the one or more segments ofthe dynamic data map.

In another embodiment, the invention provides a system for generating adata map based on a dynamically updated data set. The system includes aclient-side device. The client-side device includes a controller and isoperably connected to a communication network. The controller includes aprocessor and a non-transitory computer readable data storage medium,the processor is configured to retrieve from the medium and executecomputer readable instructions to receive a data set including one ormore data assets and generate the data map based on the received dataset. Each data asset includes four or more attributes. The data mapincludes one or more segments, and the one or more segments illustrateeach of the four or more attributes of the one or more data assets.

In another embodiment, the invention provides a system for generating adata map based on a dynamically updated data set. The system includes adatabase, a server, and a client-side device. The server includes afirst controller and is operably connected to a communication network.The first controller includes a first processor and a firstnon-transitory computer readable data storage medium. The firstprocessor is configured to retrieve from the first medium and executecomputer readable instructions to, retrieve a data set from thedatabase, transmit the data set to a client-side device over thecommunication network, receive a modified data set from the client-sidedevice, and store the modified data set from the client-side device inthe database. The data set includes one or more data assets, and eachdata asset including four or more attributes. The client-side deviceincludes a second controller and is operably connected to thecommunication network. The second controller includes a second processorand a second non-transitory computer readable data storage medium. Thesecond processor is configured to retrieve from the second medium andexecute computer readable instructions to receive the data set includingone or more data assets from the server and generate a dynamic data mapbased on the received data set. The dynamic data map includes one ormore segments. The one or more segments illustrate each of the four ormore attributes of the one or more data assets. The second processor isalso configured to retrieve from the second medium and execute computerreadable instructions to select one or more of the one or more segmentsof the dynamic data map, and limit a set of data assets loaded into anactive memory of the second controller to the data assets associatedwith the selected one or more of the one or more segments of the dynamicdata map.

In another embodiment, the invention provides a method of generating adata map based on a dynamically updated data set. The method includesretrieving a data set from a database, transmitting the data set to aclient-side device over a communication network, receiving a modifieddata set from the client-side device, and storing the modified data setfrom the client-side device in the database. The data set includes oneor more data assets, and each data asset includes four or moreattributes.

In another embodiment, the invention provides a method of generating adata map based on a dynamically updated data set. The method includesreceiving a data set including one or more data assets and generatingthe data map based on the received data set. Each data asset includesfour or more attributes. The data map includes one or more segments, andthe one or more segments illustrate each of the four or more attributesof the one or more data assets.

Before any embodiments of the invention are explained in detail, it isto be understood that the invention is not limited in its application tothe details of the configuration and arrangement of components set forthin the following description or illustrated in the accompanyingdrawings. The invention is capable of other embodiments and of beingpracticed or of being carried out in various ways. Also, it is to beunderstood that the phraseology and terminology used herein are for thepurpose of description and should not be regarded as limiting. The useof “including,” “comprising,” or “having” and variations thereof hereinare meant to encompass the items listed thereafter and equivalentsthereof as well as additional items. Unless specified or limitedotherwise, the terms “mounted,” “connected,” “supported,” and “coupled”and variations thereof are used broadly and encompass both direct andindirect mountings, connections, supports, and couplings.

In addition, it should be understood that embodiments of the inventionmay include hardware, software, and electronic components or modulesthat, for purposes of discussion, may be illustrated and described as ifthe majority of the components were implemented solely in hardware.However, one of ordinary skill in the art, and based on a reading ofthis detailed description, would recognize that, in at least oneembodiment, the electronic based aspects of the invention may beimplemented in software (e.g., stored on non-transitorycomputer-readable medium) executable by one or more processing units,such as a microprocessor and/or application specific integrated circuits(“ASICs”). As such, it should be noted that a plurality of hardware andsoftware based devices, as well as a plurality of different structuralcomponents may be utilized to implement the invention. For example,“servers” and “computing devices” described in the specification caninclude one or more processing units, one or more computer-readablemedium modules, one or more input/output interfaces, and variousconnections (e.g., a system bus) connecting the components.

Other aspects of the invention will become apparent by consideration ofthe detailed description and accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a data system according to an embodiment of theinvention.

FIG. 2 illustrates a server-side processing device according to anembodiment of the invention.

FIG. 3 illustrates a client-side processing device according to anembodiment of the invention.

FIG. 4 illustrates a client-side dynamic mapping interface forselectively modifying a data set according to an embodiment of theinvention.

FIG. 5A illustrates a dynamic data map according to an embodiment of theinvention.

FIG. 5B illustrates a client-side dynamic mapping interface for addingor modifying the dynamic data map of FIG. 5A.

FIG. 6A illustrates a dynamic data map according to an embodiment of theinvention with a map segment selected.

FIG. 6B illustrates a client-side dynamic mapping interface for addingor modifying the dynamic data map of FIG. 6A as well as informationrelated to data assets within the selected segment of FIG. 6A.

FIG. 7A illustrates a dynamic data map according to an embodiment of theinvention with a map segment selected.

FIG. 7B illustrates a client-side dynamic mapping interface for addingor modifying the dynamic data map of FIG. 7A as well as informationrelated to data assets within the selected segment of FIG. 7A.

FIG. 8A illustrates a dynamic data map according to an embodiment of theinvention with a map segment selected.

FIG. 8B illustrates a client-side dynamic mapping interface for addingor modifying the dynamic data map of FIG. 8A as well as informationrelated to data assets within the selected segment of FIG. 8A.

FIG. 9A illustrates a dynamic data map according to an embodiment of theinvention with a map segment selected.

FIG. 9B illustrates a client-side dynamic mapping interface for addingor modifying the dynamic data map of FIG. 9A as well as informationrelated to data assets within the selected segment of FIG. 9A.

FIG. 10 illustrates a client-side interface related to the translationof a data asset from one segment of a dynamic data map to another,different segment of the dynamic data map.

FIG. 11A illustrates data within a client-side dynamic data map andassociated with a selected data asset.

FIG. 11B illustrates a client-side dynamic mapping interface formodifying information associated with the selected data asset within thedynamic data map of FIG. 11A.

FIG. 12A illustrates a segment of a client-side dynamic data map andfour dimensions of mapping information.

FIG. 12B illustrates the segment of the client-side dynamic data map ofFIG. 12A and a data asset of relatively low importance and relativelychronologically recent.

FIG. 12C illustrates the segment of the client-side dynamic data map ofFIG. 12A and a data asset of medium importance and chronologicallybefore the data asset of FIG. 12B.

FIG. 12D illustrates the segment of the client-side dynamic data map ofFIG. 12A and a data asset of high importance and chronologically beforethe data asset of FIG. 12C.

FIG. 12E illustrates a client-side dynamic mapping interface formodifying dimensions of information associated with the selected dataasset within the dynamic data map of FIG. 12D.

FIG. 13A illustrates a client-side dynamic mapping interface for addinguser data to a given data set associated with a dynamic data map.

FIG. 13B illustrates a dynamic data map with user data dynamically addedto the data set using interface of FIG. 13A.

FIG. 14 illustrates a predictive map including a predicted future asset.

FIG. 15 illustrates another predictive map including a predicted futureasset.

FIGS. 16A-16F are a process for creating and modifying an asset map.

FIG. 17 illustrates a client-side dynamic mapping interface for addingassets to a map by searching for assets, uploading assets, or importingassets.

FIG. 18 illustrates a client-side dynamic mapping interface for addingsegments and assets to a map by selecting a hierarchical structure andcharacteristics of the hierarchical structure.

FIGS. 19A-19E are a process for adding segments and assets to a map.

FIG. 20 illustrates a two-dimensional view of an isolated map segment.

FIG. 21 illustrates a three-dimensional layer view of an isolated mapsegment.

FIGS. 22A-22B are a process for zooming on a map segment, extracting mapsegment layers, and collapsing segment map layers.

FIG. 23 illustrates the generation of a new map based on one or moreselected map segments.

FIG. 24 is a process for generating a new map based one or more selectedmap segments.

DETAILED DESCRIPTION

FIG. 1 illustrates a data modification and mapping system 100 that isoperable or configured to receive, store, generate, and dynamicallymodify data sets in order to generate a visual representation of thedata set based on a hierarchical data structure of the data set. Thedata modification and mapping system 100 includes a plurality ofclient-side devices 105-125, a first network 130, a second network 135,a third network 140, a server-side mainframe computer or server 145, afirst database 150, a second database 155, a server-side computer orworkstation 160, and a third-party computing or storage device 165(e.g., a server, a workstation, etc.). The plurality of client-side datainput devices 105-125 include, for example, a server 105, a personalcomputer 110, a tablet computer 115, a personal digital assistant(“PDA”) (e.g., an iPod touch, an e-reader, etc.) 120, and a mobile phone(e.g., a smart phone) 125. Each of the devices 105-125 is operable orconfigured to communicatively connect to the server 145 through thefirst network 130 and/or the second network 135 and receive a data setto be mapped from the server 145 or provide modified data sets to theserver 145. The data sets can be received from the databases 150, 155 orprovided to the databases 150, 155.

The first network 130 is, for example, a wide area network (“WAN”)(e.g., a TCP/IP based network), a local area network (“LAN”), aneighborhood area network (“NAN”), a home area network (“HAN”), orpersonal area network (“PAN”) employing any of a variety ofcommunications protocols, such as Wi-Fi, Bluetooth, ZigBee, etc. Thesecond network 135 is a cellular network, such as, for example, a GlobalSystem for Mobile Communications (“GSM”) network, a General Packet RadioService (“GPRS”) network, a Code Division Multiple Access (“CDMA”)network, an Evolution-Data Optimized (“EV-DO”) network, an Enhanced DataRates for GSM Evolution (“EDGE”) network, a 3GSM network, a 4GSMnetwork, a 4G LTE network, a Digital Enhanced CordlessTelecommunications (“DECT”) network, a Digital AMPS (“IS-136/TDMA”)network, or an Integrated Digital Enhanced Network (“iDEN”) network,etc.

The connections between the devices 105-125 and the first and secondnetworks 130 and 135 are, for example, wired connections, wirelessconnections, or a combination of wireless and wired connections.Similarly, the connections between the server 145 and the first andsecond networks 130 and 135 are wired connections, wireless connections,or a combination of wireless and wired connections. In the illustratedembodiment, the first network 130, the second network 135, and thecommunication between the devices 105-125 and the server 145 areprotected using one or more encryption techniques, such as thosetechniques provided in the IEEE 802.1 standard for port-based networksecurity, pre-shared key, Extensible Authentication Protocol (“EAP”),Wired Equivalency Privacy (“WEP”), Temporal Key Integrity Protocol(“TKIP”), Wi-Fi Protected Access (“WPA”), etc.

The third network 140 is, for example, a WAN (e.g., a TCP/IP basednetwork), a LAN, a NAN, a HAN, a PAN employing any of a variety ofcommunications protocols, such as Wi-Fi, Bluetooth, ZigBee, etc., or acellular network, such as, for example, a GSM network, a GPRS network, aCDMA network, an EV-DO network, an EDGE network, a 3GSM network, a 4GSMnetwork, a 4G LTE network, a DECT network, am IS-136/TDMA network, aniDEN network, etc. The server 145 connects to the device 165 through thethird network 140 for accessing or receiving data from the device 165.The server 145 can store the data accessed or received from the device165 and use the data to create and/or modify data sets.

FIG. 2 illustrates the server-side of the data modification and mappingsystem 100 with respect to the server 145. The server 145 iselectrically and/or communicatively connected to a variety of modules orcomponents of the system 100. For example, the illustrated server 145 isconnected to the user interface module 160, the first database 150, andthe second database 155. The server 145 includes a controller 200, apower supply module 205, and a network communications module 210. Thecontroller 200 includes combinations of hardware and software that areoperable to, among other things, dynamically modify data sets on theserver side of the data modification and mapping system 100. In someconstructions, the controller 200 includes a plurality of electrical andelectronic components that provide power, operational control, andprotection to the components and modules within the controller 200and/or data modification and mapping system 100. For example, thecontroller 200 includes, among other things, a processing unit 215(e.g., a microprocessor, a microcontroller, or another suitableprogrammable device), a memory 220, input units 225, and output units230. The processing unit 215 includes, among other things, a controlunit 235, an arithmetic logic unit (“ALU”) 240, and a plurality ofregisters 245 (shown is a group of registers in FIG. 2 ) and isimplemented using a known computer architecture, such as a modifiedHarvard architecture, a von Neumann architecture, etc. The processingunit 215, the memory 220, the input units 225, and the output units 230,as well as the various modules connected to the controller 200 areconnected by one or more control and/or data buses (e.g., common bus250). The control and/or data buses are shown schematically in FIG. 2for illustrative purposes. The use of one or more control and/or databuses for the interconnection between and communication among thevarious modules and components would be known to a person skilled in theart in view of the invention described herein.

The memory 220 includes, for example, a program storage area and a datastorage area. The program storage area and the data storage area caninclude combinations of different types of memory, such as read-onlymemory (“ROM”), random access memory (“RAM”) (e.g., dynamic RAM[“DRAM”], synchronous DRAM [“SDRAM”], etc.), electrically erasableprogrammable read-only memory (“EEPROM”), flash memory, a hard disk, anSD card, or other suitable magnetic, optical, physical, electronicmemory devices, or other data structures. The processing unit 215 isconnected to the memory 220 and executes software instructions that arecapable of being stored in a RAM of the memory 220 (e.g., duringexecution), a ROM of the memory 220 (e.g., on a generally permanentbasis), or another non-transitory computer readable data storage mediumsuch as another memory or a disc.

In some embodiments, the controller 200 or network communications module210 includes one or more communications ports (e.g., Ethernet, serialadvanced technology attachment [“SATA”], universal serial bus [“USB”],integrated drive electronics [“IDE”], etc.) for transferring, receiving,or storing data associated with the system 100 or the operation of thesystem 100. Software included in the implementation of the system 100can be stored in the memory 220 of the controller 200. The softwareincludes, for example, firmware, one or more applications, program data,filters, rules, one or more program modules, and other executableinstructions. The controller 200 is configured to retrieve from memoryand execute, among other things, instructions related to the dynamicdata modification processes and methods described herein. In otherconstructions, the controller 200 includes additional, fewer, ordifferent components.

The power supply module 205 supplies a nominal AC or DC voltage to thecontroller 200 or other components or modules of the system 100. Thepower supply module 205 is powered by, for example, mains power havingnominal line voltages between 100V and 240V AC and frequencies ofapproximately 50-60 Hz. The power supply module 205 is also operable orconfigured to supply lower voltages to operate circuits and componentswithin the controller 200 or system 100. In other constructions, thecontroller 200 or other components and modules within the system 100 arepowered by one or more batteries or battery packs, or anothergrid-independent power source (e.g., a generator, a solar panel, etc.).

The user interface module 160 includes a combination of digital andanalog input or output devices required to achieve a desired level ofcontrol and monitoring for the system 100. For example, the userinterface module 160 includes a display (e.g., a primary display, asecondary display, etc.) and input devices such as touch-screendisplays, a plurality of knobs, dials, switches, buttons, etc. Thedisplay is, for example, a liquid crystal display (“LCD”), alight-emitting diode (“LED”) display, an organic LED (“OLED”) display,an electroluminescent display (“ELD”), a surface-conductionelectron-emitter display (“SED”), a field emission display (“FED”), athin-film transistor (“TFT”) LCD, or the like.

FIG. 3 illustrates the client-side of the data modification and mappingsystem 100 with respect to the client-side devices 105-125. Theclient-side devices 105-125 include a controller 300, a power supplymodule 305, a network communications module 310, a user interface 315,and a client-side database 320. The controller 300 includes combinationsof hardware and software that are operable to, among other things,dynamically modify data sets on the client side of the data modificationand mapping system 100. In some constructions, the controller 300includes a plurality of electrical and electronic components thatprovide power, operational control, and protection to the components andmodules within the controller 300 and/or data modification and mappingsystem 100. For example, the controller 300 includes, among otherthings, a processing unit 325 (e.g., a microprocessor, amicrocontroller, or another suitable programmable device), a memory 330,input units 335, and output units 340. The processing unit 325 includes,among other things, a control unit 345, an arithmetic logic unit (“ALU”)350, and a plurality of registers 355 (shown is a group of registers inFIG. 3 ) and is implemented using a known computer architecture, such asa modified Harvard architecture, a von Neumann architecture, etc. Theprocessing unit 325, the memory 330, the input units 335, and the outputunits 340, as well as the various modules connected to the controller300 are connected by one or more control and/or data buses (e.g., commonbus 360). The control and/or data buses are shown schematically in FIG.3 for illustrative purposes. The use of one or more control and/or databuses for the interconnection between and communication among thevarious modules and components would be known to a person skilled in theart in view of the invention described herein.

The memory 330 includes, for example, a program storage area and a datastorage area. The program storage area and the data storage area caninclude combinations of different types of memory, such as read-onlymemory (“ROM”), random access memory (“RAM”) (e.g., dynamic RAM[“DRAM”], synchronous DRAM [“SDRAM”], etc.), electrically erasableprogrammable read-only memory (“EEPROM”), flash memory, a hard disk, anSD card, or other suitable magnetic, optical, physical, electronicmemory devices, or other data structures. The processing unit 325 isconnected to the memory 330 and executes software instructions that arecapable of being stored in a RAM of the memory 330 (e.g., duringexecution), a ROM of the memory 330 (e.g., on a generally permanentbasis), or another non-transitory computer readable data storage mediumsuch as another memory or a disc.

In some embodiments, the controller 300 or network communications module310 includes one or more communications ports (e.g., Ethernet, serialadvanced technology attachment [“SATA”], universal serial bus [“USB”],integrated drive electronics [“IDE”], etc.) for transferring, receiving,or storing data associated with the system 100 or the operation of thesystem 100. Software included in the implementation of the system 100can be stored in the memory 330 of the controller 300. The softwareincludes, for example, firmware, one or more applications, program data,filters, rules, one or more program modules, and other executableinstructions. The controller 300 is configured to retrieve from memoryand execute, among other things, instructions related to the dynamicdata modification processes and methods described herein. In otherconstructions, the controller 300 includes additional, fewer, ordifferent components.

The power supply module 305 supplies a nominal AC or DC voltage to thecontroller 300 or other components or modules of the system 100. Thepower supply module 305 is powered by, for example, mains power havingnominal line voltages between 100V and 240V AC and frequencies ofapproximately 50-60 Hz. The power supply module 305 is also operable orconfigured to supply lower voltages to operate circuits and componentswithin the controller 300 or system 100. In other constructions, thecontroller 300 or other components and modules within the system 100 arepowered by one or more batteries or battery packs, or anothergrid-independent power source (e.g., a generator, a solar panel, etc.).

The user interface module 315 includes a combination of digital andanalog input or output devices required to achieve a desired level ofcontrol and monitoring for the system 100. For example, the userinterface module 315 includes a display (e.g., a primary display, asecondary display, etc.) and input devices such as touch-screendisplays, a plurality of knobs, dials, switches, buttons, etc. Thedisplay is, for example, a liquid crystal display (“LCD”), alight-emitting diode (“LED”) display, an organic LED (“OLED”) display,an electroluminescent display (“ELD”), a surface-conductionelectron-emitter display (“SED”), a field emission display (“FED”), athin-film transistor (“TFT”) LCD, or the like.

The server 145 interacts over the networks 130, 135 with the variousclient-side devices 105-125 to allow the client-side devices to generatedynamic data maps based on data sets provided by the server 145. Forexample, for a given map, the server 145 provides all of the data to theclient devices 105-125 related to that map (e.g., objects or segments ofthe data map, attributes of each object and asset, etc.). The server 145provides this master or parent data set to the client device andallocates the modification and generation of new or different data setsbased on the master or parent data set to the client device 105-125. Anyadditions or modification to the master or parent data set (e.g.,including the generation of additional data subsets) can be providedfrom the client devices 105-125 to the server 145 so the server canupdate the database and data sets corresponding to the dynamic data map.In some embodiments, the server 145 compiles multiple dynamic data mapsfrom different users into a single, comprehensive data map (e.g., wherethe sub-maps are modified by different users and a supervisor ispermitted access to the combined data maps and data sets).

FIG. 4 illustrates a client-side dynamic mapping interface 400 forselectively modifying a data set received by the client device (e.g.,devices 105-125) from the server 145. The master or parent data set isused by the client device to generate a radial map 405 based on thestructure of the data within the parent data set. The interface 400includes the map 405, an author content tab 410, an advanced map toolstab 415, an add/modify segment tab 420, and an add/modify data asset tab425. Within the add/modify segment tab 420, a user can choose to modifya segment (e.g., name, etc.) using a modify segment input device, deletea segment using a delete segment input device, or add a new segmentusing an input text box and an “add new” segment input device. Althoughthe data modification and mapping system 100 can be applied to a varietyof different types of data, embodiments of the invention describedherein are described primarily with patent related assets due to therigid and defined structure of patent classification systems (e.g.,Cooperative Patent Classification codes, Derwent Classification codes,International Patent Classification codes, United States PatentClassification codes, European Patent Office Classification codes,etc.). However, different types of data are modified and mapped in otherembodiments of the invention and the invention is generally applicableto any structured data set including some form of hierarchicalinformation.

An exemplary radial map 500 is illustrated in FIG. 5A related tomattress technology. The map 500 includes a series of level-onesegments, such as air handling systems, mattress frame technology,mattress, etc. Each level-one segment can include level-two,level-three, level-four, etc., segments related to more specific aspectsof the higher level segment, as described in greater detail below. Eachsegment of the map can include one or more data assets (e.g., patents,published patent applications, etc.) related to the segment in which itappears. Each data asset can be represented with a shape and a color toconvey information to a user about, for example, the type of asset or anattribute of the asset (e.g., expired patent, un-expired patent, etc.).The segments within the map 500 are also colored such that differentsegments within the map are readily identifiable and distinguishablefrom one another. FIG. 5B illustrates a client-side dynamic mappinginterface 505 for adding to or modifying the dynamic data map of FIG.5A.

FIG. 6A illustrates a radial map 510 that includes a selected level-onesegment. With the segment selected, the map 510 highlights the selectedsegment by unselecting or greying out the other, unselected segments.FIG. 6B illustrates a client-side dynamic mapping interface 515 foradding to or modifying the dynamic data map of FIG. 6A. The interface515 also provides information related to data assets that are locatedwithin the selected segment. In the illustrated segment and interface,one data asset (e.g., one patent) is illustrated with correspondinginformation about the asset (e.g., number, title, assignee, strength,issue date, etc.). Similarly, FIGS. 7A and 7B illustrate a radial map520 and a selected level-two segment and a client-side dynamic mappinginterface 525, respectively. When the level-two segment is selected, theparent segment also remains selected (e.g., upstream segments). However,the interface 525 only lists the data assets actually located within theselected segment (e.g., not data assets within the parent segment).Similar selection and display of data assets is illustrated foradditional levels of the dynamic data map in FIG. 8A (map 530), FIG. 8B(interface 535), FIG. 9A (map 540), and FIG. 9B (interface 545).

When segments are selected, the controller 300 of the client-side device105-125 limits the data that is being processed to the data assets ofthe selected segments. For example, if the entire parent or master dataset for a dynamic data map were being processed by the client-sidedevice 105-125 as a user navigates through the dynamic data map, theclient-side device 105-125 may not have the processing power required tomanipulate the map. Client-side devices such as cell phones and tabletcomputers may have comparatively less processing power than a desktopcomputer. Rather than assuming that the client-side device has theprocessing power required to handle an entire dynamic data map, thecontroller 300 of the client-side device can instead operate on a subsetof the parent or master data set to preserve computational resources. Insome embodiments, when a segment is selected, data assets from othernon-selected segments are pruned from the active memory of thecontroller 300. As additional or different segments are selected, thedata that is loaded in active memory can be changed or updated. Fordynamic data maps that include a significant number of segments and dataassets, such control over the data that is loaded into active memoryimproves the controller 300 and the client-side device 105-125's abilityto present the dynamic data map and to operate smoothly andresponsively. In some embodiments, the controller 300 operates off ofthe original parent or master data set for the dynamic data map. Inother embodiments, the controller 300 creates a copy of the originalparent or master data set and operates off of the copy.

The controller 200, 300 of the system 100 is further operable orconfigured to create additional data sets without user intervention. Forexample, the controller 200, 300 can create data sets that thecontroller 200, 300 determines are likely to be a selected subset of theparent or master data set (i.e., corresponding to particular selectedsegments). In some embodiments, the creation of these data sets is donein the background (e.g., when computational resources are available).The created data sets can be saved by the client side device 105-125 orthe server 145 for future retrieval. By generating these data sets, alibrary of potential data sets for a given dynamic data map can becreated which allows faster operation of the map because subsets of dataassets do not need to be generated in real-time in response to userinput. Because generating subsets of data assets is computationallyexpensive and the client-side device has relatively limited resources(e.g., compared to the server 145), the server 145 can test theclient-device 105-125 to benchmark the device's processing capabilities.By doing so, the server can select one or more subsets of the parent ormaster data set (e.g., from a library of generated data subsets) andpre-load the most common or likely data subsets onto the client device105-125.

In addition to selecting segments within a dynamic data map, a user canalso select specific data assets to be moved within the dynamic data mapor modified (e.g., modifying bibliographic information, modifyingstrength, modifying importance, etc.). FIG. 10 illustrates an interface550 related to moving a data asset from one segment to another. Moving adata asset from one location in a dynamic data map to another locationin the data map, for example, de-couples the data asset from thehierarchical structure used to generate the map. In some embodiments,upon moving the data asset (e.g., dragging the asset to a different maplocation using a mouse or touch-screen interface), the data asset isre-associated with the new segment and couples the data asset to thehierarchical structure available for the new segment (e.g., the dataasset is automatically reclassified based on the user's input to movethe data asset).

When navigating a dynamic data map, such as the dynamic data map 555 inFIG. 11A, selecting a data asset opens a window that provides additionalinformation about the asset (e.g., patent publication number, issuedate, strength, comments, etc.). A user is also able to edit the dataasset by selecting an edit button using an interface such as interface560 in FIG. 11B. The interface 560 provides general information aboutthe data asset and allows the user to modify a strength, symbol, orcolor associated with the data asset.

Each data asset within a given map segment includes four or moredimensions of information. For example, FIG. 12A illustrates a mapsegment 565 that includes three data assets. Within the radial map, eachsegment conveys information about the data assets in the segment basedon the relative position of the data assets within the map. For example,the location of the segment within the larger radial map demonstrateshow broad or specific a given segment is within the hierarchical mapstructure. A segment lower in the map (e.g., a level-three segment) isgenerally narrower than a segment higher in the map (e.g., a level-onesegment). Additionally, the shape and color of a particular data assetcan convey information about the type and/or an attribute of the dataasset (e.g., expired patent, un-expired patent, a patent that has beenenforced, etc.). The segment 565 of FIG. 12A also illustrates tworelational dimensions of information that are dependent upon thepositioning of an asset within the segment. First, in the radialdirection of the map, a fourth dimension or parameter 575 (e.g., time,patent strength, patent importance, etc.) is illustrated. Extendingradially to a first end 590 of the fourth dimension 575 to a second end595 of the fourth dimension 575 conveys information about the fourthdimension 575. For example, the closer a data asset is to the first end590 of the fourth dimension 575, the lower the strength or importance ofthe data asset (e.g., an importance of 0.1). However, the closer thedata asset is to the second end 595 of the fourth dimension 575, thegreater the strength or importance of the data asset (e.g., animportance of 0.9). Second, the location of the data assetscircumferentially or along the arc of the segment illustrates a fifthdimension or parameter 570 (e.g., age of the data asset). Extendingcircumferentially along the segment's arc from a first end 580 of thefifth dimension 570 to a second end 585 of the fifth dimension 570conveys information about the fifth dimension. For example, the closer adata asset is to the first end 580 of the fifth dimension 570, the olderthe data asset (e.g., patent that issued 20 years ago). However, thecloser the data asset is to the second end 585 of the fifth dimension570, the newer the data asset (e.g., a patent that issued one year ago).The parameters corresponding to any of the disclosed dimensions of thedynamic data map can be selected or customized by the user in order togenerate a data map that conveys desirable information. FIGS. 12B, 12C,and 12D illustrate the relative locations of the three data assets inthe segment 565 (FIG. 12A). As illustrated, the strength and age of thedata assets varies with the location of the data asset within thesegment 565. A user is also able to edit the data assets within thesegment 565 by selecting an edit button and using an interface such asinterface 615 in FIG. 12E. Any of the three data assets within thesegment 565 can be modified by the user (e.g., modify a strength orsymbol associated with the data asset).

The parent or master data set received at the client device 105-125 canbe updated or modified by a user by adding segments and/or data assetsto the dynamic data map. Segments and/or assets can be added to theparent or master data set received by the client device 105-125 in avariety of ways. For example, segments and/or assets can beindividually, manually added by a user through the user interface of theclient device 105-125. In other embodiments, segments and/or assets canbe imported, searched and added, uploaded, predicted, etc. Varioustechniques for adding segments and/or assets to the parent or masterdata set for subsequent visual representation in dynamic data map aredescribed below.

FIG. 13A illustrates a dynamic data map interface 620 for individually,manually adding a segment to a data map 625 (see FIG. 13B). The addedsegment TEST is illustrated as a new level-one segment in FIG. 13B. Thenew segment is automatically placed within the data map and will beautomatically expanded or contracted based on, for example, the numberof sub-levels to the segment, the number of assets in the segment, etc.

In addition to being able to individually, manually add segments and/orassets, assets can be predictively added to a dynamic data map using,for example, one or more extrapolation or regression techniques. FIG. 14illustrates such a predictive map 700 of one or more future assets. Themap 700 is illustrated as a graph including an x-axis 705 and a y-axis710. In the illustrated embodiment, the x-axis 705 represents time andthe y-axis 710 represents asset strength. In other embodiments, they-axis represents a different characteristic, such as importance orquantity (e.g., number of assets in a given time period or interval).The map 700 includes a number of existing assets 715. The assets cancorrespond to, for example, a map or map segment such as the map segment565 illustrated in FIG. 12A. The map 700 also includes a predicted asset720. The asset 720 does not correspond to a currently existing asset.Rather, the asset 720 is an asset generated by the system 100 based onthe existing assets 715. Based on the assets 715, the system 100predicts when one or more additional assets are likely to appear (e.g.,when a new patent application will publish). A similar illustration of apredicted asset can be represented as a map or map segment, such as themap segment 800 and predicted asset 805 illustrated in FIG. 15 .

The system 100 generates predicted assets based on the number of assetsin a particular map segment and the frequency with which the assetsappear. For example, the assets in a particular map segment can beevenly disbursed within the segment or bunched in a particular portionof the segment. The position of a predicted asset varies depending onthe distribution of the assets within the segment. For example, acluster of assets for a temporally early portion of a segment followedby very few assets later in the segment suggest that a new asset is notlikely to appear in the segment. Conversely, very few assets early in asegment followed by a cluster of assets later in the segment suggestthat a new asset is likely to appear later in the segment (i.e., in thefuture).

The system 100 utilizes a variety of predictive techniques to determineor extrapolate when a new asset is likely to appear and can also, forexample, extrapolate the potential strength of that asset. As such, thesystem 100 can predict not only when a new asset may appear, but alsoother characteristics of that asset, such as strength or importance.Each prediction is based on the currently existing assets in aparticular segment. Additionally, the system 100 is capable ofpredicting one or a plurality of additional assets. In some embodiments,the number of assets that the system 100 predicts is based on thelikelihood of a new asset appearing (e.g., if an asset is very likely toappear, the system predicts several new assets). Based on the existingassets in a segment, the system 100 uses linear regression, polynomialregression, or non-linear regression techniques to predict new assets.Non-linear regression techniques include the use of power functions,logarithmic functions, trigonometric functions, exponential functions,Gaussian functions, Lorenz curves, etc. A regression trendline or curvecan be generated and/or displayed on a map (e.g., map 700 or map segment800). One skilled in the art in light of the invention described hereinwould understand how to apply the noted regression techniques to theassets in a particular map or segment representing, for example, patentassets and the assets' timing, strength, importance, etc. In someembodiments, the system 100 inputs the dates on which assets havepublished (e.g., published patent applications, patent grant dates,etc.) across a desired date range (e.g., one year, 20 years, and thelike) into any suitable regression formula to generate one or more datesupon which one or more corresponding additional patent applications orpatents are predicted to publish. Such predicted patent applications orpatents can then be illustrated in a map or map segment as predictedassets, and can have shapes and/or colors selected to differentiate themfrom other assets on the map or map segment.

In the context of the assets as patents, the timing of an assetcorresponds to patent application filing date, publication date, issuedate, etc. Predicted patent assets can similarly correspond to apredicted filing date, publication date, issue date, etc. As describedabove, a map can include assets corresponding to a particularclassification, assignee, technology, etc. As such, a plurality ofdifferent predictions can be made or combined. For example, futureassets can be predicted for two (or more) assignees in a particulartechnology area. The results of the prediction (e.g., two trendlines,predicted assets, etc.) can show convergence in the technology area.Such convergence provides an indication of where the technology area orfield is headed in the future.

FIGS. 16A-16F are a process 900 for adding new segments and/or assets toa new or existing dynamic data map, as well as modifying attributes ofsegments and/or assets in a dynamic data map. The process 900 is capableof being executed by the controller 200 of the server 145 or thecontroller 300 of the client-side devices 105-125. In some embodiments,the execution of the process 900 is divided between the controller 200and the controller 300 such that some steps of performed by the server145 (e.g., updating a parent or master data set) and other steps areperformed by the client-side devices 105-125 (e.g., updating a parent ormaster data set, selecting a segment and/or asset to modify, etc.). Thecomputer readable instructions required to execute the process 900 arestored in the respective non-transitory computer readable data storagemediums (e.g., memory 220, memory 330, etc.) associated with the server145 and the client-side devices 105-125. The process 900 is illustratedin FIGS. 16A-16F in an illustrative manner, and the process 900 caninclude additional, different, or fewer steps. In some embodiments, thesteps of the process 900 can be executed in an order other than thespecific order in which the steps of the process 900 are illustrated inFIGS. 16A-16F.

The process 900 begins with at step 905 with the controller 200, 300determining whether a new map is to be created. In some embodiments, anew map corresponds to a map where there are no parent or master datasets and a new dynamic data map is being created from nothing. In otherembodiments, creating a new map is effected from an existing set ofparent or master data and a selected portion of the parent or master setof data is used to create the new map. If no new map is going to becreated at step 905, the process 900 proceeds to step 910 where thecontroller 200, 300 determines whether an existing map is to bemodified. If no existing dynamic data map is to be modified at step 910,the process 900 returns to step 905 and waits for either a new map to becreated or a modification of an existing map to be made. If, at step910, an existing map requires modification, the process 900 proceeds tostep 915 where the controller 200, 300 determines whether an existingsegment in the dynamic data map requires modification. If an existingstep requires modification, the process 900 proceeds to control sectionB of the process 900 and FIG. 16B. If no existing segment requiresmodification, the process 900 proceeds to step 920 where the controller200, 300 determines whether a new segment is to be added to the dynamicdata map. If a new segment needs to be added to the dynamic data map,the process 900 proceeds to control section C of the process 900 andFIG. 16C. If no new segments need to be added to the dynamic data map,the process 900 proceeds to step 925 where the controller 200, 300determines whether an existing segment is to be deleted from the dynamicdata map. If an existing segment is to be deleted from the dynamic datamap, the process 900 proceeds to control section D of the process 900and FIG. 16D. If no existing segment requires deletion or removal fromthe dynamic data map, the process 900 proceeds to control section G andstep 930 of the process 900. At step 930, the controller 200, 300determines an asset is to be added or modified, the process 900 proceedsto control section E and FIG. 16E. If no assets are to be added ormodified, the controller 200, 300 determines whether an existing assetwithin a dynamic data map is to be moved (step 935). If, at step 935,the controller 200, 300 determines that an asset in the dynamic data mapis to be moved, the process 900 proceeds to control section F and FIG.16F. If no asset in the dynamic data map is to be moved, the process 900returns to control section A and step 905.

With reference to FIG. 16B and control section B of the process 900, thecontroller 200, 300 determined that an existing segment of a dynamicdata map requires modification. At step 940, the controller 200, 300determines which segment and which of the segments attributes requiresmodification. After the segment and attribute have been selected, thesegment attribute is modified (step 945) and the modified segmentattribute is saved (step 950). The modified segment attribute can besaved to, for example, the memory 220, 330. After the modifications tothe segment attribute have been made and saved, the controller 200, 300updates the dynamic data map with the modified segment attribute (step955). Following step 955, the process 900 proceeds to control section Hand FIG. 16A.

With reference to FIG. 16C and control section C of the process 900, thecontroller 200, 300 determined that a new segment was to be added to thedynamic data map. At step 960, the controller 200, 300 receivesinformation related to a name for the new segment of the map. Thecontroller 200, 300 receives the information from, for example, the userinterface 160, 315. After the segment has been named, the attributes ofthe new segment are selected (step 965) and the new segment of thedynamic data map is saved (step 970). The new segment and itsattribute(s) can be saved to, for example, the memory 220, 330. Afterthe new segment and its attributes have been saved, the controller 200,300 updates the dynamic data map with the new segment (step 975).Following step 975, the process 900 proceeds to control section I andFIG. 16A.

With reference to FIG. 16D and control section D of the process 900, thecontroller 200, 300 determined that an existing segment was to bedeleted from the dynamic data map. At step 980, the controller 200, 300receives information related to which existing segment of the dynamicdata map is to be deleted. The controller 200, 300 receives theinformation from, for example, the user interface 160, 315. After theinformation related to which existing segment of the map is to bedeleted, the controller 200, 300 confirms (e.g., by prompting a user forconfirmation) that the selected segment is to be deleted (step 985).After the controller 200, 300 receives confirmation of the segment to bedeleted, the segment is deleted from the dynamic data map (step 990).The controller 200, 300 then updates the dynamic data map with thedeleted segment removed from the dynamic data map (step 995). Deleting asegment and/or asset(s) from a dynamic data map correspondingly removesthe data related to that segment and/or asset(s) from a data set beingused to populate the dynamic data map. In some embodiments, such adeletion corresponds to the removal of data from a parent or master dataset. In other embodiments, the deleted data is removed from a subset ofthe parent or master data set that was generated by the controller 200,300 but that data remains in the parent or master data set. For example,a parent or master data set can be maintained by the controller 200 inthe server 145. The parent or master data set is provided to thecontroller 300 of a client-side device 105-125. Modifications, includingdeletions of data, are made on the data set received by the client-sidedevice 105-125. After the data set has been modified, the modified dataset can be used to overwrite the parent or master data set at the server145 or can be saved at the server 145 as a new data set. The new dataset can then, for example, be designated as a new parent or master dataset for a dynamic data map that can be separately accessed and modifiedby a user. Following step 995, the process 900 proceeds to controlsection G and FIG. 16A.

As described above, in control section G of the process 900, thecontroller 200, 300 determines whether an asset is to be added to adynamic data map, an existing asset in the dynamic data map is to bemodified, or if an existing asset in a dynamic data map is to be movedto a new or different position in the dynamic data map. If an asset isto be added or modified, the process 900 proceeds to control section Eand FIG. 16E. With reference to control section E and FIG. 16E, thecontroller 200, 300 determines whether a new asset is to be added to adynamic data map (step 1000). If, at step 1000, a new asset is to beadded to the dynamic data map, the controller 200, 300 creates an assetdata item to be added to a data set (e.g., a master or parent data setfor the dynamic data map). The controller 200, 300 enters an asset namefor the new asset in the data set (step 1005), enters asset attributesfor the new asset in the data set (step 1010), and selects a symbol forthe new asset in the data set (step 1015). The controller 200, 300enters this information for the new asset based on, for example,information received through the user interface 160, 315. As describedherein, a new asset can also be imported, searched and added, uploaded,predicted, etc., and does not strictly require that a user manuallyenter all information for a new asset. After all of the information forthe new asset has been entered, the controller 200, 300 adds the newasset data to the data set for the dynamic data map (step 1020) andupdates the dynamic data map with the new asset (step 1025).

If, at step 1000, an existing asset is to be modified (rather than a newasset being added), the controller 200, 300 selects an asset to modify(step 1030). The controller 200, 300 receives information related towhich existing asset of the dynamic data map is to be modified from, forexample, the user interface 160, 315. After the asset to be modified isselected, the controller 200, 300 modifies one or more attributes of theasset (step 1035). The controller 200, 300 receives information relatedto how to modify the existing asset of the dynamic data map from, forexample, the user interface 160, 315. After modification, the controller200, 300 saves the modified asset attributes to the data set for thedynamic data map (step 1040) and updates the dynamic data map with themodified asset attribute (step 1045). Following step 1045, the process900 returns to control section G and FIG. 16A.

Returning to control section G of the process 900, and assuming that nonew assets need to be added or existing assets need to be modified, thecontroller 200, 300 determines whether an existing asset in a dynamicdata map is to be moved (step 935). If no existing assets in the dynamicdata map need to be moved, the process 900 returns to control section Aand step 905. If an existing asset in the dynamic data map is to bemoved, the process 900 proceeds to control section F and FIG. 16F. Withreference to control section F and FIG. 16F, the controller 200, 300selects an asset to move (step 1050). The controller 200, 300 receivesinformation related to which existing asset of the dynamic data map isto be moved from, for example, the user interface 160, 315. After theinformation related to which existing asset of the map is to be moved,the controller 200, 300 confirms (e.g., by prompting a user forconfirmation) that the selected asset is to be moved (step 1055). Afterthe controller 200, 300 receives confirmation of the asset to be moved,the asset is moved to a new or different location in the dynamic datamap (step 1060). The controller 200, 300 then updates the dynamic datamap with the asset moved to the new or different location in the dynamicdata map (step 1065). Moving the asset to a new or different location inthe dynamic data map results in, for example, the controller 200, 300modifying associations of the asset within the data set for the dynamicdata map. For example, the associations for the asset with respect toits segment within the map, higher-level segments within the map, andlower-level segments can all be updated to reflect the new position ofthe asset within the dynamic data map and within the hierarchicalstructure of the data set. Following step 1065, the process 900 returnsto control section A and FIG. 16A.

FIG. 17 illustrates a client-side dynamic data mapping interface 1100for adding assets to a dynamic data map. An author content tab 1105provides a variety of mechanisms for adding assets to a new or existingdynamic data map. Within the author content tab 1105 is an add/modifyasset sub-tab 1110. The add/modify asset sub-tab 1110 in FIG. 17provides three primary mechanisms for adding assets to a dynamic datamap. The mechanisms include using a search query box 1115 with optionaladvanced search options 1120, an uploading assets interface 1125, and animport assets interface 1130. The search query box 1115 is operable orconfigured to receive inputs from a user related to a search query. Thesearch query can be entered using, for example, natural language textsearching, Boolean searching, etc. In some embodiments, the box 1115functions like a patent search database where further values, such aspatent classifications, specific patent numbers, assignee names,inventor names, etc. can be entered. Such search fields can be populatedin the box 1115 or using the advanced search options 1120. The searchcapabilities of the add/modify asset sub-tab 1110 are generallywell-known in the art and do not need to be described in great detail.The interface 1100 differs significantly from the art, however, afterthe search results have been retrieved and some or all of the resultsare subsequently added to a data set for a dynamic data map. Similarly,data assets can be added to a new or existing dynamic data map byuploading a file that contains data assets and attributes or informationabout the data assets using the upload assets interface 1125. The uploadassets interface 1125 functions similar to a conventional uploadinginterface in which a user is prompted to select a file (e.g., aspreadsheet) from a local computer, a networked computer, or some otherstorage device where the file is actually stored. Additionally, assetscan be added to a new or existing dynamic data map by importing dataassets using the import assets interface 1130. The import assetsinterface 1130 functions similarly to the upload assets interface 1125.However, rather than prompting a user for a specific file to upload, theuser may be prompted to provide a web address, a link to an existingdynamic data map, etc. Like adding assets via search query, after dataassets have been retrieved by uploading or importing, some or all of thedata assets are subsequently added to a data set for a dynamic data map.

FIG. 18 illustrates another client-side dynamic data mapping interface1200 for adding segments and/or assets to a dynamic data map. Theinterface 1200 is specific to an embodiment of the invention in whichsome or all of the data assets in a dynamic data map are or will bepatent-related assets (e.g., issued patents, patent applications, etc.).The interface 1200 includes an author map content tab 1205 and anadd/modify segment sub-tab 1210. Although using the add/modify segmentsub-tab, the interface 1200 can also add assets by virtue of addingsegments to a dynamic data map. For example, although segments can beadded, the segments are not necessarily empty (i.e., simply ahierarchical structure that includes no data assets). Rather thesegments can include data assets (e.g., patents) that are added to adynamic data map by virtue of adding a segment within which the dataassets are located. The add/modify segment sub-tab 1210 includes aninput device (e.g., a drop down menu or similar selection device) forselecting a hierarchical structure for the segments to be added to thedynamic data map. The hierarchical structure can be defined by, forexample, patent classification systems such as Cooperative PatentClassification codes, Derwent Classification codes, International PatentClassification codes, United States Patent Classification codes,European Patent Office Classification codes, etc. In some embodiments, aknown classification system is not used and an ad hoc hierarchicalstructure can be created and used. After a hierarchical structure hasbeen selected, a select asset type interface 1220 allows a user toselect specific types of assets to effectively filter out some of thedata assets that would otherwise be added to the dynamic data map. Inthe illustrated embodiment, asset types include in force patents,expired patents, U.S. patents, U.S. Patents and foreign patents, andregional patents. Specific regions can be selected with an input device1225 (e.g., a drop down menu). Additionally, the interface 1200 can alsoinclude a search box similar to the search box 1115 and advancedsearching option to refine the number of patent data assets that areadded to the dynamic data map. After the desired patent data segmentsand data assets have been selected, the dynamic data map is updated withthe selected segments and data assets.

FIGS. 19A-19E are a process 1300 for adding segments and/or assets to adynamic data map. The process 1300 allows the controller 200, 300 to addmultiple segments and/or assets without requiring a user toindividually, manually add each segment and/or asset. The process 1300is capable of being executed by the controller 200 of the server 145 orthe controller 300 of the client-side devices 105-125. In someembodiments, the execution of the process 1300 is divided between thecontroller 200 and the controller 300 such that some steps of performedby the server 145 (e.g., updating a parent or master data set) and othersteps are performed by the client-side devices 105-125 (e.g., updating aparent or master data set, selecting segments and/or assets to upload orimport, etc.). The computer readable instructions required to executethe process 1300 are stored in the respective non-transitory computerreadable data storage mediums (e.g., memory 220, memory 330, etc.)associated with the server 145 and the client-side devices 105-125. Theprocess 1300 is illustrated in FIGS. 19A-19E in an illustrative manner,and the process 1300 can include additional, different, or fewer steps.In some embodiments, the steps of the process 1300 can be executed in anorder other than the specific order in which the steps of the process1300 are illustrated in FIGS. 19A-19E.

The process 1300 begins with the controller 200, 300 determining whethera new dynamic data map is to be created or an existing dynamic data mapis to be modified (step 1305). If no new dynamic data map is to becreated or no existing dynamic data map is to be modified, the process1300 returns to step 1305. If, at step 1305, a new dynamic data map isto be created or an existing dynamic data map is to be modified, theprocess 1300 proceeds to step 1310 and the controller 200, 300determines the manner(s) in which data will be added to a data set forthe dynamic data map. First, at step 1310, the controller 200, 300determines whether data will be added to a data set using a searchquery. Data can be added using a search query as previously describedabove with respect to FIGS. 17 and 18 , and will also be described infurther detail below. If, at step 1310, the controller 200, 300determines that data is to be added to a data set using a search query,the process 1300 proceeds to control section J and FIG. 19B. If, at step1310, the controller 200, 300 determines that data is not to be enteredusing a search query, the controller 200, 300 determines whether data isto be added to a data set via upload (step 1315). Data can be added viaupload as previously described above with respect to FIG. 17 , and willalso be described in further detail below. If, at step 1315, thecontroller 200, 300 determines that data is to be added to a data setvia upload, the process 1300 proceeds to control section K and FIG. 19C.If, at step 1315, the controller 200, 300 determines that data is not tobe entered via upload, the controller 200, 300 determines whether datais to be added to a data set by importation (step 1320). Data can beadded using by importation as previously described above with respect toFIG. 17 , and will also be described in further detail below. If, atstep 1320, the controller 200, 300 determines that data is to be addedto a data set by importation, the process 1300 proceeds to controlsection L and FIG. 19D. If, at step 1320, the controller 200, 300determines that data is not to be entered by importation, the controller200, 300 determines whether any data that is to be added to a dynamicdata map is to be, or has been filtered (step 1325). Data to be added toa data set for a dynamic data map can be filtered, for example, asdescribed above with respect to FIG. 18 , and will also be described infurther detail below. If, at step 1325, the controller 200, 300determines that data to be added to the data set is to be filtered, theprocess 1300 proceeds to control section M and FIG. 19E. If, at step1325, no data to be added to the data set is to be filtered, the process1300 returns to control section Q and step 1305.

With reference to FIG. 19B and control section J of the process 1300,the controller 200, 300 determined that data is to be added to a dataset using a search query. At step 1330, the controller 200, 300 entersasset search terms. Asset search terms can be entered as a string ofwords or characters. For example, natural language searching or Booleansearching can be used to enter search terms for searching one or moredatabases of information (e.g., databases 150, 155, third-partycomputing or storage device 165) for assets to add to the dynamic datamap. The databases 150, 155 are, for example, databases for the UnitedStates Patent and Trademark Office, the European Patent Office, etc. Insome embodiments, the databases 150, 155 correspond to proprietydatabases of information that are not generally accessible outside of anorganization (e.g., a corporation) or government entity. The third-partycomputing or data storage device 165 is, for example, a server,database, or another device that is accessible via the Internet to thegeneral public for retrieving information. The controller 200, 300receives the information related to asset search terms from, forexample, the user interface 160, 315. After asset search terms have beenadded at step 1330, asset search results are retrieved from, forexample, the databases 150, 155 or device 165. After the assets havebeen retrieved, all or a portion of the retrieved assets can be selectedto be added to a dynamic data map (step 1340). Assets can be selectedindividually or as a group. For example, the search query can returnsearch results in a structured or spreadsheet like manner that allowsindividual or groups of assets to be conveniently selected. After theassets to be added to the dynamic data map have been selected at step1340, the selected assets are added to a data set for the dynamic datamap (step 1345) and the controller 200, 300 updates the dynamic data mapwith the selected assets (step 1350). Following step 1350, the process1300 proceeds to control section N and FIG. 19A.

With reference to FIG. 19C and control section K of the process 1300,the controller 200, 300 determined that data is to be added to a dataset via upload. At step 1355, a file containing assets is selected. Thefile can be selected, for example, from the memory 330 of theclient-side device 105-125, the database 320, or can be received orretrieved through the communication networks 130, 135. The file is, forexample, a spreadsheet containing structured data sets or a similar filewhere information or data can be compiled and saved. After the file hasbeen selected, the controller 200, 300 uploads the selected file (step1360) and retrieves the assets (and asset related information) from thefile (step 1365). After the assets are retrieved from the file, theassets are added to a data set for the dynamic data map (step 1370) andthe controller 200, 300 updates the dynamic data map with the uploadedassets (step 1375). Following step 1375, the process 1300 proceeds tocontrol section 0 and FIG. 19A.

With reference to FIG. 19D and control section L of the process 1300,the controller 200, 300 determined that data is to be added to a dataset by importation. At step 1380, a source of data assets is selected.The source can be, for example, another data set for another dynamicdata map, a publicly available asset list (e.g., from a website), etc.After the source of data assets has been selected, the controller 200,300 retrieves the data assets from the source (step 1385). After theassets have been retrieved, all or a portion of the retrieved assets canbe selected to be added to a dynamic data map (step 1390). The selectedassets are then added to a data set for the dynamic data map (step 1395)and the controller 200, 300 updates the dynamic data map with theimported assets (step 1400). Following step 1400, the process 1300proceeds to control section P and FIG. 19A.

With reference to FIG. 19E and control section M of the process 1300,the controller 200, 300 determined that asset data is to be filtered. Insome embodiments, the controller 200, 300 filters data assets after theyhave been added to a data set of a dynamic data map. Additionally oralternatively, the controller 200, 300 filters data assets before thedata assets are added to a data set for a dynamic data map (e.g., atsteps 1340, 1365, and/or 1390 of process 1300). Filtering data assetscan also be used to create a new dynamic data map for particular typesof data assets. For example, from an existing dynamic data map for whichthere are no new data assets to add, the existing data assets in thedynamic data map can be filtered. The filtered set of data assets (e.g.,a subset of a parent or master data set) can be stored as a new parentor master data set corresponding to data assets meeting the selectedfilter settings. At step 1410, asset types are selected to filter dataassets. Asset types correspond to higher level attributes of data assets(e.g., utility patents, issued patents, etc.). The controller 200, 300then selects asset attributes to be filtered (step 1415). Assetattributes are generally lower-level attributes of data assets (e.g.,country/region that issued patent, patent assignee, patent applicant,etc.). After data asset types and asset attributes for filtering areselected, the controller 200, 300 filters the assets (step 1420). Thecontroller 200, 300 then updates (or creates) a dynamic data map withthe data assets that remain after filtering (step 1425). Following step1425, the process 1300 proceeds to control section Q and FIG. 19A.

In addition to creating and/or modifying an existing dynamic data map asdescribed above, the system 100 is also capable of blending existingmaps together into a single map. For example, based on permissionswithin an organization, some users may have access to more data mapsthan others. As a result, it is beneficial for some users to createand/or modify dynamic data maps and allow another user (e.g., with ahigher level of permissions) to combine two or more dynamic data mapsinto a single dynamic data map. In some embodiments, when two maps arecombined, the system 100 (via controller 200, 300) uses the entirety ofeach of the two maps to create a new combined map. The controller 200,300 can create new first-level segments for each of the original mapsand make the first-level segments of the original maps second-levelsegments in the combined map. Similar techniques can be used whencombining more than two dynamic data maps together into a single dynamicdata map.

FIG. 20 illustrates a zoomed and isolated segment 1505 of a dynamic datamap 1500. In addition to being able to view an entire dynamic data mapand select segments within the dynamic data map, the controller 200, 300can also be used to isolate and zoom a particular segment of the map1500. In some embodiments, the controller 200, 300 can be used to zoomand isolate multiple segments within a dynamic data map. The segment1505 of FIG. 20 includes two data assets 1510 and 1515. The remainingsegments of the dynamic data map 1500 are made invisible or at leastpartially transparent with respect to the selected segment 1505 to makethe segment 1505 the focus of the displayed map. In some embodiments,only the data assets of the selected segment 1505 are visible when aparticular segment is isolated and zoomed. As described above, when oneor more segments are selected, the data that is loaded into activememory is limited to preserve computational resources of the controller300. In some embodiments, zooming in on a particular segment of adynamic data map similarly limits the data loaded into active memory tothe data assets related to the zoomed segment.

In addition to the zoomed and isolated segment 1505 of FIG. 20 , thecontroller 200, 300 can also generate a three-dimensional (“3-D”) viewof a selected segment 1600, as illustrated in FIG. 21 . The segment 1600includes a first data asset 1605 and a second data asset 1610. Includedin the display of the segment 1600 is asset information 1615 for thefirst data asset 1605 and asset information 1620 for the second dataasset. The asset information 1615 and asset information 1620 arepresented as information boxes extending from their respective dataassets. The information boxes can provide information about the dataassets (e.g., basic attributes of the data asset). In some embodimentsall of the attributes of a given data asset are displayed as assetinformation. In other embodiments, a subset of the attributes for a dataasset is presented in the asset information and a user can select aparticular data asset to see additional attributes.

In addition to a three dimensional view of the segment 1600, thecontroller 200, 300 is also able to separate the segment 1600 intolayers to better or more effectively illustrate the data assets in thesegment 1600. For example, the controller 200, 300 can separate thesegment 1600 into a first segment 1625 including the first data asset1605 and a second segment 1630 including the second data asset 1610. Thecontroller 200, 300 separates the data assets into layers based on, forexample, a particular attribute of the data assets. As an illustrativeexample, one layer of the segment 1600 can correspond to expired patentsand another layer can correspond to in force patents. However, anyattribute of the data assets can be used to separate a segment intolayers and a user can select specific data assets (i.e., even without acommon attribute) and generate a layer that includes the selectedassets. Like the two-dimensional representations of segments, the 3-Drepresentation includes a first dimension of information 1635 and asecond dimension of information 1640 for the segment 1600. However,because the segment 1600 is illustrated in 3-D, a third dimension ofinformation 1645 can be incorporated into the segment 1600.

FIGS. 22A-22B are a process 1700 for viewing selected segments within adynamic data map. The process 1700 allows the controller 200, 300 tozoom in on one or more selected segments, show data assets within thesegment(s), separate segments into layers, etc. The process 1700 iscapable of being executed by the controller 200 of the server 145 or thecontroller 300 of the client-side devices 105-125. In some embodiments,the execution of the process 1700 is divided between the controller 200and the controller 300 such that some steps of performed by the server145 (e.g., isolating a segment and the segment's data assets, separatingsegments into layers, etc.) and other steps are performed by theclient-side devices 105-125 (e.g., isolating a segment and the segment'sdata assets, etc.). The computer readable instructions required toexecute the process 1700 are stored in the respective non-transitorycomputer readable data storage mediums (e.g., memory 220, memory 330,etc.) associated with the server 145 and the client-side devices105-125. The process 1700 is illustrated in FIGS. 22A-22B in anillustrative manner, and the process 1700 can include additional,different, or fewer steps. In some embodiments, the steps of the process1700 can be executed in an order other than the specific order in whichthe steps of the process 1700 are illustrated in FIGS. 22A-22B.

The process 1700 begins with the selection of a segment within a dynamicdata map by the controller 200, 300 (step 1705). The controller 200, 300receives information related to which segment of the dynamic data map isto be selected from, for example, the user interface 160, 315. After thecontroller 200, 300 has selected a segment, the controller 200, 300adjusts the display of the dynamic data map such that the selectedsegments are zoomed in on with respect to the other segments of thedynamic data map (step 1710). For example, the selected segment iszoomed and centered in a display portion of the user interface 160, 315.After zooming on the selected segment, the zoomed segment can beisolated from some or all of the other segments of the dynamic data map(step 1715), as illustrated previously with respect to FIG. 20 . Afterthe zoomed segment has been isolated, the controller 200, 300 determineswhether a segment layer view is to be entered (step 1720). Thecontroller 200, 300 receives information related to entering the segmentlayer view from, for example, the user interface 160, 315. If thesegment layer view is to be entered, the process 1700 proceeds tocontrol section R of process 1700 and FIG. 22B. If the segment layerview is not to be entered, the process 1700 proceeds to step 1725 wherethe assets of the isolated and zoomed segments are shown within thesegment. In some embodiments, the asset shapes, basic asset attributes,or the like are illustrated within the isolated segment view without auser having to scroll over or individually select an asset. After agiven time period, after a new segment is selected, after a reset buttonis selected, etc., the isolated segment view is reset to a normal viewof the dynamic data map (step 1730). The process 1700 then proceeds tocontrol section S and step 1705.

If, at step 1720, the segment layer view was selected, the process 1700proceeds to control section R and FIG. 22B. With reference to controlsection R and FIG. 22B, a 3-Dimensional (“3-D”) segment view isillustrated (step 1735). The 3-D segment view is illustrated in FIG. 21. In the 3-D segment view, assets and asset attributes or information isshown (step 1740). When the 3-D segment view is active, the controller200, 300 can separate the segment into asset layers, as previouslyillustrated in FIG. 22B (step 1745). If, at step 1745, the segment layerview is not selected, the 3-D segment view (e.g., showing a singlesegment layer) remains. However, if the segment layer view is selected,the controller 200, 300 extracts segment layers based on, for example,asset attributes (step 1750). Step 1750 can be repeated multiple timesautomatically by the controller 200, 300 or by command of a user tocontinue to extract asset layers from the 3-D segment. After eachsegment layer is extracted, the assets in each segment layer arerespectively shown along with asset attributes or information. Thesegment layer view and 3-D segment view are particularly beneficial whenviewing a segment that includes a significant number (e.g., greater than20) assets because the views are able to provide a less cluttered visualdisplay and individual asset information without requiring a user toscroll over or individually select an asset. After a given time period,after a new segment is selected, after a reset button is selected, etc.(step 1760), the segment layer view is collapsed and the view is resetto a normal view of the dynamic data map (step 1765). The process 1700then proceeds to control section S and step 1705.

In addition to adding segments and/or assets to a dynamic data map aswas described above, existing segments and data assets within a dynamicdata map can also be used to generate a new dynamic data map. Forexample, FIG. 23 illustrates the creation of a dynamic data map from oneor more segments in an existing dynamic data map. A group of segments1800 in an existing dynamic data map includes three levels of segments.The group 1800 includes a first-level segment 1805, a second-levelsegment 1810, and a third-level segment 1815. When the controller 200,300 determines that a new dynamic data map is to be created (e.g., basedon inputs from user interface 160, 315), the group 1800 is used topopulate the new dynamic data map. As illustrated in FIG. 23 , the newdynamic data map includes the same segments 1805, 1810, and 1815.Because only one segment was selected from each of the first, second,and third segment levels, each segment in the new dynamic data mapcorresponds to a full circle. If additional segments were selected(e.g., an additional segment at any layer), the corresponding level ofthe new dynamic data map is proportionally broken up between theselected segments (e.g., one-half of the circle for each of twosegments). For each of the selected segments of the original dynamicdata map that becomes a new segment in the new dynamic data map, thedata assets that were present in the original selected data segment arecopied and/or transferred to the corresponding segments of the newdynamic data map. The data assets that are copied and/or transferred tothe new dynamic data map are positioned in the segments of the newdynamic data map based on their attributes from the original dynamicdata map (e.g., importance, age, etc.) to convey the same dimensions ofinformation.

FIG. 24 is a process 1900 by which the controller 200, 300 generates anew dynamic data map from one or more selected segments of an existingdynamic data map. The process 1900 is capable of being executed by thecontroller 200 of the server 145 or the controller 300 of theclient-side devices 105-125. In some embodiments, the execution of theprocess 1900 is divided between the controller 200 and the controller300 such that some steps of performed by the server 145 (e.g.,generating a new dynamic data map, etc.) and other steps are performedby the client-side devices 105-125 (e.g., selecting segments, etc.). Thecomputer readable instructions required to execute the process 1900 arestored in the respective non-transitory computer readable data storagemediums (e.g., memory 220, memory 330, etc.) associated with the server145 and the client-side devices 105-125. The process 1900 is illustratedin FIG. 24 in an illustrative manner, and the process 1900 can includeadditional, different, or fewer steps. In some embodiments, the steps ofthe process 1900 can be executed in an order other than the specificorder in which the steps of the process 1900 are illustrated in FIG. 24.

The process 1900 begins with the selection of one or more segmentswithin an existing dynamic data map by the controller 200, 300 (step1905). The controller 200, 300 receives information related to whichsegments of the dynamic data map are to be selected from, for example,the user interface 160, 315. After one or more segments are selected,the selected segments are highlighted (e.g., to distinguish selectedsegments from unselected segments) (step 1910). At step 1915, thecontroller 200, 300 determines whether a new dynamic data map is to begenerated. The controller 200, 300 receives information related towhether to generate a new dynamic data map from, for example, the userinterface 160, 315. If, at step 1915, the controller 200, 300 is togenerate a new dynamic data map, the controller 200, 300 generates a newdynamic data map based on the selected segments (step 1920), aspreviously illustrated in FIG. 23 . The data assets that were present inthe selected segments are copied or moved into the new dynamic data map,and their relative positions within each of the new segments is modifiedor updated to reflect changes in segment size. After the new dynamicdata map is generated, the new dynamic data map and its data sets aresaved (step 1925). The new dynamic data map can be saved to, forexample, the memory 220, the memory 330, the database 150, the database155, the database 320, etc. In some embodiments, the new dynamic datamap is generated by the controller 300 in a client-side device 105-125and then transferred to the controller 200 of the server 145 forpermanent storage. In other embodiments, the new dynamic data map can bestored in multiple locations, including the server 145. If the newdynamic data map is stored, for example, somewhere other than the server145 (e.g., database 320), the dynamic data map and its data sets areavailable to be imported using the process 1300 for creating ormodifying a dynamic data map.

Thus, the invention provides, among other things, a data modificationand mapping system for the dynamic modification of data sets on both theclient side and server side. Various features and advantages of theinvention are set forth in the following claims.

1-20. (canceled)
 21. Non-transitory computer-readable medium storinginstructions that, when executed by an electronic processor, perform aset of functions, the set of functions comprising: receiving, from aserver device over a communication network, a data set retrieved fromone or more databases, the data set including a plurality of dataassets, each of the plurality of data assets including a plurality ofattributes; generating and displaying a user interface including a datamap in a normal view based on the received data set, the normal view ofthe data map including a plurality of segments, the plurality ofsegments including a first segment including a plurality of graphicalrepresentations positioned within the first segment, each of theplurality of graphical representations associated with one specific dataasset of the plurality of data assets and each of the plurality ofgraphical representations including a plurality of dimensions whereineach dimension is associated with one of the plurality of attributes ofthe one specific data asset associated with the graphicalrepresentation, wherein a first dimension of the plurality of dimensionsof each of the plurality of graphical representations includes aposition of the graphical representation within the first segment; andin response to receiving user input through the user interface,generating and displaying within the user interface the data map in amodified view, the modified view isolating at least a portion of thedata map, the portion of the data map including one of the plurality ofgraphical representations or at least one of the plurality of segments,the isolated portion of the data map displayed in a different formcompared to other graphical representations of the plurality ofgraphical representations or other segments of the plurality of segmentson the data map.
 22. The non-transitory computer readable medium ofclaim 21, wherein the user input includes a selection of one of theplurality of segments and wherein the isolated section of the data mapincludes the selected one of the plurality of segments displayed in adifferent form compared to other segments of the plurality of segments.23. The non-transitory computer readable medium of claim 21, wherein theuser input includes a selection of one of the plurality of segments andwherein the isolated section of the data map includes the selected oneof the plurality of segments displayed with asset information for eachof a subset of the plurality of data assets represented within theselected one of the plurality of assets.
 24. The non-transitory computerreadable medium of claim 21, wherein the user input includes a selectionof one of the plurality of graphical representations and wherein theisolated section of the data map includes asset information displayedfor a specific one of the plurality of data assets represented by theselected one of the plurality of graphical representation.
 25. Thenon-transitory computer readable medium of claim 21, wherein the userinput includes a filtering setting and wherein the isolated section ofthe data map includes a subset of the plurality of graphicalrepresenting a subset of the plurality of assets meeting the filteringsettings.
 26. The non-transitory computer readable medium of claim 21,wherein the user input includes a zoom input and wherein the isolatedsection of the data map includes a zoomed in view of at least one of theplurality of segments.
 27. The non-transitory computer readable mediumof claim 26, wherein, in response to receiving the user input, othersegments of the plurality of segments in the data map are displayedinvisible or at least partially transparent in the isolated view. 28.The non-transitory computer readable medium of claim 21, wherein theuser input includes a three-dimensional view input and wherein theisolated section of the data map includes a three-dimensional view of atleast one of the plurality of segments.
 29. The non-transitory computerreadable medium of claim 28, wherein the three-dimensional view of theat least one of the plurality of segments includes asset information foreach of the plurality of graphical representations included in the atleast one of the plurality of segments.
 30. The non-transitory computerreadable medium of claim 29, wherein the asset information includes aninformation box extending from each of the plurality of graphicalrepresentations included in the at least one of the plurality ofsegments.
 31. The non-transitory computer readable medium of claim 21,wherein the user input includes a layer input and wherein the isolatedsection of the data map includes at least one of the plurality ofsegments displayed separated into a plurality of layers.
 32. Thenon-transitory computer readable medium of claim 31, wherein theplurality of layers separate data assets represented by each graphicalrepresentations included in the at least one of the plurality ofsegments based on one of the plurality of attributes.
 33. Thenon-transitory computer readable medium of claim 21, wherein in responseto a predetermined time period or receiving second user input, resettingthe dynamic map to the normal view.
 34. The non-transitorycomputer-readable medium of claim 21, wherein a second dimension and athird dimension of the three or more dimensions include a shape and acolor.
 35. The non-transitory computer-readable medium of claim 34,wherein at least one of the shape and the color represents whether thedata asset associated with the graphical representation is expired. 36.The non-transitory computer-readable medium of claim 21, wherein theposition represents an age of the data asset associated with thegraphical representation.
 37. The non-transitory computer-readablemedium of claim 21, wherein the first dimension includes a radialposition within the first segment and wherein a second dimension ofplurality of dimensions includes a circumferential position within thefirst segment.
 38. A method for generating a dynamic data map, themethod comprising: receiving, from a server device over a communicationnetwork, a data set retrieved from one or more databases, the data setincluding a plurality of data assets, each of the plurality of dataassets including a plurality of attributes; generating and displaying auser interface including a data map in a normal view based on thereceived data set, the normal view of the data map including a pluralityof segments, the plurality of segments including a first segmentincluding a plurality of graphical representations positioned within thefirst segment, each of the plurality of graphical representationsassociated with one specific data asset of the plurality of data assetsand each of the plurality of graphical representations including aplurality of dimensions wherein each dimension is associated with one ofthe plurality of attributes of the one specific data asset associatedwith the graphical representation, wherein a first dimension of theplurality of dimensions of each of the plurality of graphicalrepresentations includes a position of the graphical representationwithin the first segment; and in response to receiving user inputthrough the user interface, generating and displaying within the userinterface the data map in a modified view, the modified view isolatingat least a portion of the data map, the portion of the data mapincluding one of the plurality of graphical representations or at leastone of the plurality of segments, the isolated portion of the data mapdisplayed in a different form compared to other graphicalrepresentations of the plurality of graphical representations or othersegments of the plurality of segments on the data map.
 39. The method ofclaim 38, wherein the user input includes a selection of one of theplurality of segments and wherein the isolated section of the data mapincludes the selected one of the plurality of segments displayed in adifferent form compared to other segments of the plurality of segments.40. The method of claim 38, wherein the user input includes a selectionof one of the plurality of graphical representations and wherein theisolated section of the data map includes asset information displayedfor a specific one of the plurality of data assets represented by theselected one of the plurality of graphical representation.
 41. Themethod of claim 38, wherein the user input includes a filtering settingand wherein the isolated section of the data map includes a subset ofthe plurality of graphical representing a subset of the plurality ofassets meeting the filtering settings.
 42. A system for generating adynamic data map, the system comprising: a client-side device includinga controller and operably connected to a communication network, thecontroller including a processor and a non-transitory computer readabledata storage medium, the processor configured to retrieve from themedium and execute computer readable instructions to: receive, from aserver device over a communication network, a data set retrieved fromone or more databases, the data set including a plurality of dataassets, each of the plurality of data assets including a plurality ofattributes; generate and display a user interface including a data mapin a normal view based on the received data set, the normal view of thedata map including a plurality of segments, the plurality of segmentsincluding a first segment including a plurality of graphicalrepresentations positioned within the first segment, each of theplurality of graphical representations associated with one specific dataasset of the plurality of data assets and each of the plurality ofgraphical representations including a plurality of dimensions whereineach dimension is associated with one of the plurality of attributes ofthe one specific data asset associated with the graphicalrepresentation, wherein a first dimension of the plurality of dimensionsof each of the plurality of graphical representations includes aposition of the graphical representation within the first segment; andin response to receiving user input through the user interface, generateand display within the user interface the data map in a modified view,the modified view isolating at least a portion of the data map, theportion of the data map including one of the plurality of graphicalrepresentations or at least one of the plurality of segments, theisolated portion of the data map displayed in a different form comparedto other graphical representations of the plurality of graphicalrepresentations or other segments of the plurality of segments on thedata map.
 43. The system of claim 42, wherein the user input includes aselection of one of the plurality of segments and wherein the isolatedsection of the data map includes the selected one of the plurality ofsegments displayed in a different form compared to other segments of theplurality of segments.
 44. The system of claim 42, wherein the userinput includes a selection of one of the plurality of graphicalrepresentations and wherein the isolated section of the data mapincludes asset information displayed for a specific one of the pluralityof data assets represented by the selected one of the plurality ofgraphical representation.
 45. The system of claim 42, wherein the userinput includes a zoom input and wherein the isolated section of the datamap includes a zoomed in view of at least one of the plurality ofsegments.